Method For Producing A Component Covered With A Wear-Resistant Coating

Abstract

The invention relates to a method for the production of a component, especially gas turbine component, coated with a wear-protection coating, especially a corrosion-protection coating or erosion-protection coating, with the following steps: a) providing a component (10) to be coated on a component surface (13); b) at least partially coating the component (11) on its component surface with an at least two-layered or at least two-plied wear-protection coating (14), whereby the wear-protection coating (14) encompasses at least one relatively soft layer (15) and at least one relatively hard layer (16); c) surface densifying the at least partially coated component on its coated component surface.

Description

The invention relates to a method for the production of a component, especially a gas turbine component, coated with a wear-protection coating, especially a corrosion-protection coating or erosion-protection coating.

During their operation, gas turbine components are subjected to a high wear, especially through oxidation, corrosion or also erosion. It is therefore known from the prior art, to provide gas turbine components with corresponding wear-protection coatings. However, through the application of a wear-protection coating, the so-called HCF service life duration of the base material of the coated gas turbine component is reduced. In order to compensate this reduction of the HCF service life duration caused by the coating, it is already known from the prior art to subject the gas turbine component, which is to be coated, to a surface consolidation or densification, especially through ball blasting or shot peening, before the coating. Through the subsequent coating of the gas turbine component, which typically proceeds at elevated coating temperatures, however, a portion of the densification or consolidation achieved by the shot peening is again diminished or dissipated. Thus, the surface densification of the component to be coated, before the coating thereof with the wear-protection coating, is only conditionally effective.

It is already know from the JP 11-343565-A, to apply a coating of an intermetallic material onto a component of a titanium based alloy. The coating of the intermetallic material, according to this prior art, is subjected to a diffusion heat treatment and, if applicable, a surface densification by ball blasting or shot peening. In that regard, however, the problem arises that the brittle intermetallic diffusion coating is damaged during the surface densification.

Beginning from this, the problem underlying the present invention is to provide a novel method for the production of a component coated with a wear-protection coating.

This problem is solved by a method for the production of a component coated with a wear-protection coating according to patent claim 1. According to the invention, the method encompasses at least the following steps: a) providing a component that is to be coated on a component surface; b) at least partially coating the component on its component surface with an at least two-layered or at least two-plied wear-protection coating, whereby the wear-protection coating encompasses at least one relatively soft layer and at least one relatively hard layer; c) surface densifying the at least partially coated component on its coated component surface.

In the sense of the present invention, it is proposed to apply an at least two-layered or at least two-plied wear-protection coating onto the surface of the component that is to be coated, and to subsequently subject the thusly coated component to a surface densifying through preferably ball blasting or shot peening. The at least two-layered wear-protection coating has at least one relatively soft layer and at least one relatively hard layer. Through the inventive combination of the coating of the component with a multilayer wear-protection coating with subsequent surface densifying, the energy applied to the wear-protection coating during the surface densifying can be reduced or dissipated without the existence of the danger of damages of the wear-protection coating.

Preferred further developments of the invention arise from the dependent claims and the following description. Example embodiments of the invention are explained more closely in connection with the drawing, without being limited hereto. Thereby:

FIG. 1 shows a gas turbine vane that is to be coated, in a schematic side view;

FIG. 2 shows a schematic cross-section through a wear-protection coating;

FIG. 3 shows a schematic cross-section through an alternative wear-protection coating; and

FIG. 4 shows a diagram for the clarification of the compressive stress gradient or course that arises in the coated component upon carrying out the inventive method.

In the following, the present invention will be described in greater detail with reference to the FIGS. 1 to 4.

In an exemplary fashion, FIG. 1 shows a gas turbine vane 10, which comprises a vane blade 11 as well as a vane root or pedestal 12, as a component to be coated with the inventive method. The provided or prepared gas turbine vane 10 shall now be coated, with the inventive method, in the area of the surface 13 of the vane blade 11 with a wear-protection coating, preferably with a corrosion-protection coating or erosion-protection coating.

For this purpose, in the sense of the inventive method, one proceeds in such a manner that an at least two-layered or at least two-plied wear-protection coating is applied onto the surface 13. Thus, for example FIG. 2 shows that a two-plied or two-layered wear-protection coating 14 of a relatively soft metallic layer 15 and a relatively hard ceramic layer 16 is applied onto the surface 13 of the vane blade 11. The relatively hard metallic layer 15 is applied directly onto the surface 13 and has a material composition that is adapted to the material composition of the vane blade 11. FIG. 3 shows a wear-protection coating 17 that is built-up of several relatively soft metallic layers 15 as well as several relatively hard ceramic layers 16. The concrete number of the relatively hard ceramic layers as well as the concrete number of the relatively soft metallic layers is of subordinate significance for the present invention and is up to the selection of the expert in the field addressed here.

In the sense of the present invention, the component coated with the wear-protection coating 14, 17 is subsequently subjected to a surface densifying through especially ball blasting or shot peening. The energy applied to the wear-protection coating 14 or 17 during the shot peening can be elastically diminished or dissipated in the relatively soft metallic layers 15 due to the above described multilayer construction of the wear-protection coating. There is then no danger of damages of the relatively hard ceramic layers 16.

With the inventive method it is possible, after the coating of a component with a wear-protection coating embodied as a multilayer coating system, to establish an optimal stress gradient or course or distribution over the wear-protection coating as well as the component through subsequent surface densifying, without the existence of the danger of damages of the wear-protection coating.

Thus, FIG. 4 shows a diagram in which the depth of the coated component beginning from the surface thereof is indicated on the horizontally extending axis 18, and the compressive stress induced in the component with the aid of the inventive method is indicated on the vertically extending axis 19. The surface of the un-coated component is illustrated with the line 20; thus the area to the left of the line 20 relates to the wear-protection coating, the area to the right of the line 20 relates to the component as such. With the inventive method, the compressive stress gradient or course or distribution characterized with the reference number 21 can be realized over the depth of the coated component.

In the use of the inventive method for the production of a component coated with a wear-protection coating, the vibration strength of the base material of the coated component is fully maintained. With corresponding selection of the parameters for the shot peening or surface densifying, furthermore a smoothing effect can be achieved on the surface of the coated component.

As already mentioned, the inventive method is preferably applied for the coating of gas turbine vanes, which are formed of a titanium based alloy or nickel based alloy. Thus, for example vanes of a turbine or a compressor of an aircraft engine can be coated with the inventive method.

In closing, it is pointed out that the relatively soft metallic layers can also be embodied as porous layers. Furthermore it is possible to arrange a graded material layer between a relatively soft metallic layer and a relatively hard ceramic layer. The layers are preferably applied onto the surface of the component to be coated, by a PVD (Physical Vapor Deposition) process.

Claims

1-7. (canceled)

8. Method for the production of a component, coated with a wear-protection coating, especially a corrosion-protection coating or erosion-protection coating, with the following steps:

a) providing a component (10) to be coated on a component surface (13) thereof;

b) at least partially coating the component (11) on its component surface with an at least two-layered or at least two-plied wear-protection coating (14; 17), whereby the wear-protection coating (14; 17) comprises at least one relatively soft layer (15) and at least one relatively hard layer (16);

c) surface densifying the at least partially coated component on its coated component surface, in such a manner that an optimal stress distribution is established over the wear-protection coating and the component.

9. Method according to claim 8, characterized in that the wear-protection coating (14; 17) comprises at least one relatively soft metallic layer (15) and at least one relatively hard ceramic layer (16).

10. Method according to claim 8, characterized in that the wear-protection coating (17) comprises several relatively soft metallic layers (15) and several relatively hard ceramic layers (16).

11. Method according to claim 8, characterized in that a gas turbine component is provided as the component (10) and is at least partially coated.

12. Method according to claim 11, characterized in that the gas turbine component is a gas turbine vane, which is coated on a vane blade surface thereof.

13. Method according to claim 8, characterized in that the surface densifying of the component on its coated component surface is carried out by blasting.

14. Method according to claim 8, characterized in that the surface densifying is carried out by ball blasting or shot peening.